Multiplying and dividing machine



Oct. 28, 1952 5. BRAND ETAL MULTIPLYING AND DIVIDING MACHINE l4 Sheets-Sheet 1 Filed Sept. 22, 1948 Oct. 28, 1952 s. BRAND EI'AL MULTIPLYING AND DIVIDING MACHINE l4 Sheets-Sheet 2 Filed Sept. 22, 1948 58(Fig. Ia)

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Oct. 28, 1952 5. BRAND ETAL MULTIPLYING AND mvmmc; MACHINE l4 Sheets-Sheet 3 Filed Sept. 22. 1948 27 AccJ g7v Anal 27 ff VALLL'E 404M Oct. 28, 1952 5. BRAND :EI'AL 2,615,624

MULTIPLYING AND DIVIDING MACHINE Filed Sept. 22. 1948 14 Sheets-Shoat 4 Bnuentor:

1952 s. BRAND ETAL 2, 15,624

MUL'IIIPLYING AND DIVIDING MACHINE Filed Sept. 22. 1948 14 Sheets-Sheet 5 lnventor: (IL BRAND e B muzz Amus fa Gttorneg Oct. 28, 1952 s. BRAND EI'AL 2,615,624

' MULTIPLYING AND nrvmmc MACHINE Filed Sept. 22. 1948 14 Sheets-Sheet 6 0 many- 3nventor:

C(ttom Oct. 28, 1952 5. BRAND ETAL 2,615,624

MULTIPLYING AND DIVIDING MACHINE Filed Sept. 22, 1948 14 Sheets-Sheet 8 3 5- DIVISOR DlVlSOR (A004) (A004) 0111109110 0001115 11 111111 111111 o1v191z-0 00119111 (1100.192) (A005) 789 999210 (1100.192) (A005) 1111111111111 1111111, 11111111111111 1111111 ENTER 991097770 000000 364,! 99995018102229 999999 MULIbyI- 199 +1----9 7 994 MULIbyJ- 199 +599999 91102250 +1---- sc4'.1 57102250 +999999 1+ 799----- -1--- s114 "19999921099999 -1--- $5 19202250 90- 8 04 10202259 +909999 ".2+ 15711--- 2--- 12999999019999 2--' '2'422250 +90---- ?c4 V 2422250 +911999 ".2 1510--- 2--- s1121 .299999911421999 2-- if v I H p 55250 9111- 902 55250 +912299 ".5+ 59450 5- SHI ".5+9999999950549 5 (Complement 01 87696) INVENTORS 99mm 5,9900 Y E 9222; $5 119 ATTORNEY Oct. 28, 1952 5. BRAND ETAL 2,615,624

MULTIPLYING AND DIVIDING MACHINE Filed Sept. 22. 1948 14 Sheets-Sheet l0 1/ F/?/1 Compmenfs INVENTORS 1 E 5AM L ammo ATTORNEY g 0d. 28, 1952 5 BRAND ET AL MULTIPLYING AND DIVIDING MACHINE Filed Sept. 22. 1948 14 Sheets-Sheet 11 TEJU.

[Al/FER 5 INVENTORS SAMUEL BRAND BY VALLEE ADAMS Oct. 28, 1952 Filed Sept. 22. 1948 I io 45 so l55/6'0ZZ5ZM5/6' 45 90 w m 225270316560 4590 Iii/6022527015560 5. BRAND r MULTIPLYING AND DIVIDING MACHINE ES- 46' 90 A315 /60 225 270 360 14 Sheets-Sheet l2 ATTORNEY Patented Oct. 28, 1952.

UNITED STATES PATENT OFFICE MULTIPLYIN G AND DIVIDING MACHINE Application September 22, 1948, Serial No. 50,574

21 Claims. 1 This invention relates to calculating machines of the electrically controlled type and more particularly to machines in which multiplying and dividing operations are carried out.

The principal object of the invention is to' provide a multiplying-dividing machine in which common mechanism is employed to a great extent in carrying out both types of computation to the end that the structure of such machine is greatly simplified.

A more specific object of the invention is to provide a dividing mechanism in which a dividend is successively reduced by repeatedly subtracting multiples of the divisor employing only the multiples 2 times and 5 times the divisor and also 1 times the divisor. A comparing mechanism is provided which repeatedly compares the highest ordered divisor digit with the highest ordered dividend digit and selects 1, 2 or 5 as the multiple for the next subtraction.

In carrying out multiplication, a multiplier is successively reduced by subtracting 1, 2 or 5 from the highest order thereof. A testing mechanism repeatedly inspects the highest order of the multiplier and selects one of these digits with the procedure continuing until the multiplier is reduced to zero.

For dividing, a quotient accumulator is provided for summing the digits 1, 2 and 5, with appropriate denominational allocation until the capacity of the apparatus is reached, while for multiplying a product accumulator is provided for summing multiples of the divisor with appropriate denominational allocation until the multiplier is reduced to zero;

In both multiplying and dividing, when an overdraft occurs, the testing and comparing proceed nevertheless, but instead of a subtracting operation in accordance with the resulting selection, the digit 1, 2 or 5 (for multiplying) or 1, 2 or 5 times the divisor (for dividing) is added, followed by a further test continuing until the overdraft has been balanced, i. e., until the remainder changes from a negative value back to positive.

The accumulating mechanism employed in the machine is of the so-cailed cyclic type in which an amount may be entered during a so-called cycle of operation. -The 2 and 5 times multiples are formed by means of a partial products form:

ing device in which right and left hand components of partial products are separately obtained and successively entered into the accumulator during a single operating cycle.

A particular feature of the invention resides in the novel arrangement employing only the l, 2 and 5 times multiples of the divisor and multiplier, and in the handling of the partial products so that right and left hand components are entered into the accumulator during a single cycle of operation.

A more specific object of the invention is to provide improved start and stop controls for a cyclically operable accumulator to enable the same to expeditiously receive 1, 2 or 5 times multiples of a factor or 9s complements thereof during a single cycle of operation.

A still further object of the invention is to provide improved column shift devices by which entries into the accumulators are controlled.

Another object resides in the provision of novel overdraft detecting devices which function prior to the completion of the entering that results in an overdraft and thereby anticipates the occurrence of such overdraft and conditions subsequent machine operations to the end that a saving of time is realized.

Other objects of the invention will be pointed out in the following description and claims and illustrated in the accompanying drawings, which disclose, by way of example, the principle of the invention and the best mode, which has been contemplated, of applying that principle.

In the drawings:

Figs. la, 1b, 1c, 1d, 1e, and 1] taken together and arranged horizontally in the order named constitute a wiring diagram of the electric circuits of the machine.

Fig. 2 sets forth the mathematical procedure involved in carrying out a specific multiplying example.

Fig. 3 sets forth the procedure followed by the machine in carrying out the example of Fig. 2 indicating the successive settings of the accumulators involved.

Fig. 4 sets forth the mathematical procedure involved in carrying out a specific dividing example.

Fig. 5 sets forth the procedure followed by the machine in carrying out the example of Fig. 4

indicating the successive settings of the accumulators involved.

Fig. 6 sets forth the trial quotient digit selected for compared values of the divisor and dividend digits.

Fig. 7 is a view of one order of an accumulator.

Fig. 8 is a time chart of the cam controlled contacts of the machine.

Fig. 9 is a chart showing the period of rotation of the adding wheels when multiplying by 1.

Fig. 10 is a chart showing the period of rotation of the adding wheels when multiplying by 2.

Fig. 11 is a chart showing the period of rotation of the adding wheels when multiplying by 5.

Figs. 12a and 1212 taken together and arranged horizontally in the order named constitute a sequence diagram showing the relative periods of energization of several of the relays involved in the handling of a multiplying problem through a plurality of cycles.

Figs. 13a and 1327 taken together and arranged horizontally in the order named constitute a sequence diagram showing the relative periods of energization of several of the relays involved in the handling of a dividing problem through a plurality of cycles.

Figs. 14- and 1-5 are diagrams setting forth the mathematical procedure involved in dividing operations where remainders are involved.

The accumulating mechanism The accumulating mechanism is of the well known type disclosed in the Lake et al. Patent 2,328,653, granted September 7, 1943, and one unit or order thereof is shown in Fig. 7. Its operation briefly is as follows. 7

A constantly rotating shaft l0 driven from a suitable source of power has secured thereto a gear ii for each accumulating unit or order. This gear meshes with and drives a gear (not shown) integral with driving ratchet freely rotatable on a stud i 3. Also free on stud 43 is an element or wheel E4 to which is pivoted a dog 85 lying in the plane of ratchet l2 and normally held out of engagement therewith. As more fully explained in the patent referred to, this disagreement is maintained through the interception by a tooth IS on a lever ll of a disk it. When lever I1 is rocked counterclockwise the disk i8 is released and, as a result, dog it engages ratchet l2 and is driven thereby together with accumulating element l4. At a selected point in the cycle, lever ll is rocked back into intercepting position and effects uncoupling of the accumulating element. A cycle of operation, represented by a revolution of shaft I0, is divided into sixteen so-called cycle points designated as 9, 8, 7, 6, 5, l, 3, 2, l, 0, 11, 12, 13, 14, 15 and 16. To enter any significant digit, clutching is effected at the correspondingly numbered cycle point, and later declutching at the 0 cycle point will leave the accumulating element or wheel 24 advanced a corresponding amount. The driving ratio is such that wheel l4 advances a tenth of a revolution for each cycle point of engageme it and thus has ten rotative positions representative of the ten digits.

When wheel l4 stands at its rotative position 9, a carry lever rocks to close 9s carry contaste 2! and, when the wheel passes from 9 to 0 position, 10s carry contacts 22 are closed and latched as shown. To effect a carry entry of one unit, lever i7 is rocked counterclockwise after the 0 point in the cycle, and one point later it is rocked back again to eiiect uncoupling. A pin 24 is timed to release the latched carry lever 20 after this carry period in the cycle.

A magnet 25 designated Start, when energized, will rock lever ll counterclockwise to start rotation of the accumulating wheel M, and a second magnet 25 designated Stop, when energized, will rock lever I! in reverse direction to stop rotation of the wheel. This second magnet is employed for operations wherein the 9s complement of a digit is entered by initially energizing Start magnet 25 at the 9 point in the cycle and thereafter energizing Stop magnet at the cycle point corresponding to the value of the digit whose its complement is to be entered.

As usual in this type of accumulator, each wheel M has connected thereto a so-called readout brush 26 (shown diagrammatically in the din cult, Figs. 1c and 16) which takes any of ten positions with relation to a series of contact segments 21 to effect an electrical connection between the segment and a common conductor 28. In the actual accumulator, the segments El and conductor 28 are circularly disposed as is well known but in the circuit they are illustrated in a linear manner for more convenient explanation and circuit tracing.

The separate units or orders are grouped to form several accumulators designated ACO. l, ACC. 2, A00. 3 (Fig. 1c) and A00. 4 (Fig, 1e).

A brief explanation will first be given of the mathematical steps involved in the solution of a problem in multiplication.

Referring to Fig. 2, the factors 789 and 87693 are to be multiplied. As a preliminary, the multiplier 87 693 is entered into the multiplier accumulator in the orders indicated and the multiplicand is entered into its accumulator. An examination is made of the highest significant digit in the multiplier, and in accordance therewith the values 1, 2 or 5 are algebraically combined with the multiplier. The digit selection is in accordance with the following table which shows for each of the digits 1 to 9 the multiplier selected, with the plus digit values grouped in the upper part of the table and the minus digit values grouped in the lower part of the table.

MULTIPLIE R SELECTION n Digit Multiplier 1 selects 1 2 selects 2 3 selects 5 4 sclccts 5 5 selects 5 6 selects 5 7 selects 5 8 selects l0 9 selects l0 1 selects 2 2 selects 2 3 selects 5 4 selects 5 5 selects 5 6 selects 5 7 selects l0 8 selects l0 9 selects 10 1 l s I Concurrently with this subtraction, 1 times the multiplicand 789 is entered into the product accumulator in appropriatedenominational allocation so that, after the first step or cycle of operation, the multiplier accumulator contains the negative remainder and the product accumulator contains what is in effect times the value of the multiplicand.

A further and subsequent inspection of the highest digit of the remainder shows it to be a negative 1 which from the table (-1 selects 2) calls for a multiplier of 2. Accordingly, the 2 is entered additively in the same order as the 1 of the multiplier and the algebraic summation results in the positive remainder 7693; Concurrently, 2 times the multiplicand is entered subtractively in the product accumulator with the positive result of 6312. At this point the product accumulator represents 10 times, minus 2 times, or 8 times the multiplicand.

The third selection in accordance with the plus digit value 7 calls for a multiplier of 5 (see table above where +7 selects 5) which is entered negatively in the multiplier accumulator to obtain the positive remainder 2693 and the concurrent entry of 5 times the multiplicand advances the product accumulator to 67065.

From the foregoing, it is readily seen that the multiplying operation is essentially one in which the highest significant digit of the multiplier is inspected together with its sign and a selection of the values 2 or 5 is made in accordance with the foregoing table. The selected digit is algebraically combined with the multiplier to reduce it in the highest order with special consideration for the plus 8 and 9 digits and the minus 7, 8 and 9 digits which call for selection of the value 1 with a column shift to the left.

Continuing, the repeated inspection of the successive remainders and entry of the 1, 2 and 5 multiples of the multiplicand, together wit entry of the 1, 2 and 5 digits, will cause the multiplier to ultimately reduce to 0, and for the example chosen the product accumulator will stand at 69,189,777 at such time to represent the final product.

In Fig, 3 the steps of Fig. 2 are repeated to show the settings of the accumulator elements in the machine. The accumulators employed are normally reset to9s in all orders and the factors are initially represented as indicated by their 9s complement. Thus, the multiplier accumulator is set to represent 9,912,306. The plus sign to the left thereof indicates that the true value of the entry is positive.

The initial inspection will select the digit 1 and the algebraic summation will result in the value 12,307 of negative sign. The successive steps involved can be readily followed by keeping in mind that, when an. amount is entered additively, it takes the form of the 9's complement and, if entered negatively or subtractively, it appears as a true number so that, with the steps carried out in correspondence with Fig. 2, the multiplier will be reduced to a condition where 9s are present in all orders and the product accumulator contains the 9s complement of the product 69,189,777.

Circuit diagram The circuits involved in carrying out the multiplying problem of Fig. 2 will now be explained in connection with the diagram of Figs. 1a. to If. For the purposes of simplicity of explanation, it will be assumed that the multiplier and multiplicand'values are set up in their respective accumulators by direct positioning of brushes 26.

In the diagram are represented a number of cam controlled contacts prefixed with the letter C. Their controlling cams are driven by the contantly running cyclic shaft l0 (Fig. 7) and the timing of the contacts is as shown in the diagram (Fig. 8).

For purposes of simplicity in the disclosure, accumulator 4 is represented solely by its readout device 26, 27, 28 (Fig. 1e), inasmuch as for a multiplying operation it is set up to represent the multiplicand and such setting is not changed throughout the operation.

Referring to Fig. 1c, the multiplier is set up in accumulator I and brushes 25 of this accumulatorwill be set to represent the 9s complement 9,912,306 according to Fig. 3. The multiplicand is set up on accumulator 4 (Fig. 1e) by having the related brushes 26 positioned to represent the complement 999,210. As a further prelimi nary, several plug connections to the accumulators are madeand these will be pointed out at the time that their effectiveness is explained.

First cycle Referring to Fig. 1f, the multiply key is depressed to close contacts 30 which will complete a circuit from main line 3|, Wire 32, contacts CIB, contacts 30, pickup winding of relay MPi to ground. The relay will close its e contacts to provide a holding circuit through wire 33 and f contacts of relay R36 to line 3|. A parallel holding circuit also extends from Wire 33, through cam contacts CH, so that relay MPI will now remain energized until relay R36 is energized and contacts C|| open. The sequence of operations is set forth in Figs. 12a and 12b which may be followed in conjunction with the circuit diagram. Relay MPI closes its a contacts and completes a circuit from line 3|, Wire 32, contacts CIB, 30, 0. contacts of relay MPI, pickup winding of calculate relay CAL to ground. This relay closes its a contacts to provide a holding circuit therefor which parallels the holding circuits of relay MPI. A further circuit extends from contacts 30, through the 17 contacts of relay MP| to relay R23, and this relay closes its a contacts to provide a holding circuit through contacts C8.

During the period that contacts C8 are closed, a circuit is traceable from line 3|, wire 32, contacts C8, c contacts of relay R23, shift control relay SCI to ground. A parallel circuit extends through the b contacts of relay R23 and to relay SC4. Thus, as a result of the energization of relay R23, the shift control relays SCI and S04 are energized, and these will close their a contacts to hold through contacts C9 to the end of the first cycle as indicated in Fig. 12a. Briefly, at the beginning of operations, relay R23 by controlling energization of relays SCI and S04 efiects the maximum column shift condition for testing the highest orders of the multiplier accumulator. as willbe explained presently. As indicated in Fig. 12a, interlock relay INT is energized during the first cycle, through a circuit traceable from line 3| (Fig. 1e) m contacts of relay X5, a contacts of relay X2, s contacts of relay XI, and 0 contacts of relay CAL to relay INT (Fig. 1d). Relay INT opens back circuit preventing contacts generally designated a (Fig. 1d) and also shifts contacts designated b and 0.

Referring to Fig. lo, a circuit is now traceable from line 3|, contacts C3, b contacts of relay CAL (now closed), e contacts of relay Z4, c contacts of relay SC4 (shifted), c contacts of relay Z2, contacts of relay SCI (shifted), 02 contacts of relay ZI to the common conducting strip 28 of the next to the highest order of accumulator I. In this order, brush 2!; is set at 9 (see Fig. 3), so that the circuit will continue through the related brush to the 9 segment 21, thence through Wire 34 (Fig. 1d), 73 contacts of balance relay BAL and relay RSI to ground. The energization of relay RIM indicates that in the order tested there is no significant true digit, and it will immediately recondition the circuits to make a test of the next lower order during the period that the contacts C5 are closed, that is, within the same cycle.

With the a contacts of relay R3I now closed (top of Fig. 1c) the parallel testing circuit extends from line 3 I, contacts C3, 17 contacts of relay CAL, a contacts of Ri-BI, w contacts of SCAi (shifted), f contacts of Z 2, 01 contacts of Z2, d contacts of SCI (shifted), e contacts of ZI to the next conducting strip 28. In this order, the brush T26 is set at 1 so that the circuit continues to the 1 segment and thence through the 1 wire of the group designated 35 (Fig. 1d), 76 contacts of relay BAL, 7' contacts of relay MP2 (now shifted as will presently be explained), 8 contacts of relay 8 contacts of relay X5, a winding of relay A t to ground. Relay XIQ closes its contacts designated t to complete a parallel circuit from the 52 contacts of relay MP2 through the t contacts of XI!) and the pickup winding of relay Xi to ground. Relays XI and XIG close their a contacts to provide holding circuits through con 1 tacts Cl.

Relay MP2 was previously energized through a circuit from line SI, contacts CI (Fig. is), d contacts of relay MPI (closed), relay MP2 (Fig. id) to ground. The period of energization of relay MP2 is slightly longer than the period during which the testing contacts C3 are closed.

Upon closure of contacts C4 in the first cycle, a circuit is traceable from line 3|, contacts C (Fig. 1]), 1) contacts of relay S04 (closed), I) contacts of relay RSI (shifted), 1) contacts of SC2, 1' contacts of relay SCI, pickup winding of shift relay Slit to ground. Relay SH l will close its a contacts to provide a holding circuit through contacts C5. The relay SI-Id controls the column shift circuits through which multiples of the multipler are entered into the product accumulator and also controls the entry into the multiplier accumulator.

Briefly recapitulating the operations during the first cycle, the shift control relays S04 and SCI are first energized to direct the first test impulse from contacts C3 (Fig. 10), through the position five steps to the left of the units order of the multiplier, which is the second highest order. It may be pointed out at this time that there are three such relays designated SC l, S02 and SCI (Fig. 1]) which singly effect shifts of l, 2 and 1 steps respectively. Thus, with SCfi and SCi energized, there is a 5 step shift; SC! alone gives a 4 step shift; SCZ and SCI together give a 3 step shift; CS2 alone gives a 2 step shift; SCI alone gives a 1 step shift; and if none are energized the initial test circuit goes through the lowest or units order.

If the order (second highest) so tested contains a 9 (true 0), the relay RSI is energized to effect an immediate shift of the test circuit path to test the next lower order, so that no extra time is required beyond the period of closure of contacts C3 for testing two successive'orders of the multiplier. Since the initial 5 step shift is found to be too great, circuits are set up to obtain the following entries with only a 4 step shift by causing energization of the shift relay SE4. The mathematical condition (an 8 in the highest significant order, Fig. 2) however calls for a column shift by energizing relay XII! to in effect change the shift condition back to a 5 step shift for purposes of allocating the 1 entry in the multiplier accumulator and the 789 entry in the product accumulator.

The SC (shift control) relays select the orders to be tested and control the SH (shift) relays which select the orders to receive the 1, 2 or 5 value and the multiplicand multiple, these conditions being modified if an additional shift is called for.

Inspection of the circuit network. of Fig. 1) Will show that, if relay R3I is not in energized condition when contacts C4 close, circuits will be completed through the contacts of the SC relays to energize the corresponding SH relays; that is, if SC4 is energized, it will cause energization of SE4; if S02 is energized, it will. cause energization of S112; if SCI is energized, it will cause cnergization of SHI and combinations thereof. If, however, relay R35 has been energized, the relays energized will represent one unit less than the energized SC relays. Thus, SC@, SC! will energize SI-I4; SC l will energize SE12 and SCl will energize SE2; SCf will ener ize and SCI will energize none.

In Fig. 2 the SC and SH relays that the energized throughout the successive t as the example are designated. l hus, ii sally SC l and SCI are energized to control testing in the two positions indicated and will cause SH i during entry of l and 789 for four pi which is increased one step because relay been energized.

co shift, .2519 has Second cycle Entering muZtipZier1.-During the second cycle the digit 1 is to be subtractively entered in the multiplier accumulator as indicated in Fig. 3. As a preliminary, the accumulator entering circuits are first conditioned to receive the amount as a true entry, that is, in an additive manner by rotating the appropriate adding wheels in accordance With the value of the digit.

Contacts CI'I (Fig. 11)) close to prepare the accumulators to receive the entries, for example, accumulator I is to be conditioned to subtract a 1. In order to do this, it is necessary to energize the minus relay MI (Fig. 1c) and shift its related contacts. In Fig. 1b a circuit extends from line 3I, through contacts CI? to a series of sockets 40 and thence through a plug connection GI (Fig. 1a) to a socket 12 designated. by a minus sign, p contacts of relay BAL, relay MI wire as, r contacts of relay X2, r contacts of relay X5, contacts CI5 to ground. Relay M E shifts its a contacts whose common contacts are wired to the Start magnets 25 of accumulator i. For purposes of simplification, only four orders are illustrated for the accumulators E and S as all are alike, and these are indicated (top of Figs. 1a and 1b) as 6, 5, 2 and 1. For accumulator 5, all seven orders are shown.

The entering circuit for the digit 1 is now traceable as follows: from line 3| (Fig. 19) wire 44, to

the brush of emitter El (driven from shaft Ill) at the 1 time in the cycle, when the rotating contact brush engages the 1 segment, thence through the 1 wire of the group designated 45 (Fig. 1d),

1 contacts of relay X2, m-contaots of X5, a contacts of INT (now closed) to the 8 wire of the group designated 35 (Fig. 1e), right hand a contacts of relay DV2, the 8 wire-of the group designated 46, which continues through c contacts of relay CAL to a plug socket 41 from which a connection 48 is made to socket 49 (Fig. 1a) related to the units order of. accumulator I. From here the circuit extends through the n contacts of XI!) (shifted), m contacts of'a. relay T, 'm'contacts of relay SH4 (which is now energized), and thence down through the. h contactsof 81-12, 71 contacts of SHI, left hand a contacts of MI (shifted) to the start magnet 25in the hundreds of thousands order (second highest): of accumulator I. It is thus seen @that SH, causesa four place shift and XIO causes an additional step to efiect a total shift of five places'to theileft of the. units order.

Energization of'start magnet 25 at this. 1 time will engage the related adding'wheel' and it will advance one step, after which the corresponding stop magnet will be energized through a circuit traceable from line 31 (Fig. 1b), spot of emitter E3, 71. contacts of the X5. relay, h and 1 contacts of the X2 relay, i contacts of Xtov common wire 50 (Fig. 1a) extending over and through all the 1) contacts of the plus relayAI to the stop magnets 25 and ground. In this manner the wheel in the hundreds of thousands order of accumulator I is advanced one. step. Inthe other orders, the stop magnet energization is, of course, an idle operation, since no preceding. start operation was initiated in these orders. In Fig. 9 is shown the extent of rotation of the adding, wheel for each digit entry duringaddingandsubtracting operations.

At the carry time in the circuit, which is initiated at the 12 index point position, the emitter E3 will complete a. circuitfrom line 3| (Fig. 1b) through the 12segment, of the emitter to wire 5 I, over to the tens carry contacts22yin the hundreds of thousands order of accumulator I, wherein the tens contacts 22 are now closed, thence to the highest order position in which the 9 contacts H are closed. thence through wire 52 (Figs. 1b and 10) to the 9 segment 21 in the highest order brush 26 (set at.9), thecommon strip 28;,contacts C5 to balance relay BAL and ground which will hold through contacts CID.

With this arrangement there isa balancev test concurrent with the tenscarrycircuit completion which in efiect. anticipates that, when the carry is completed, the accumulator will have changed from a 9 setting to a 0 setting, thus indicating that the true value of the number in the accumulator has changed from a. positive to a negative value. v

The carry circuit also branches from the highest order of the accumulator (Fig. 1a) through the plug connection 53, the 9's contact 2| in the lowest order to enter the usual fugitive; 1 in theunits order by completing circuitsto the start magnet thereof at the 12 time in the cycle, through the 11 contacts of relay MI (now deenergized). Then at the 13 time the emitter E3, (Fig. lb) sends another stop impulsetothe: wiret5ll, through h contacts of X2 and X5. to the stop. magnets, and through a contacts of relay AI. Also, at the carry time the usual carry impulse will be directed to i the highest orderstart magnet for the example under consideration. I

Entering 1X789.As the emitter El (Fig; 16) rotates in the second cycle, it completes a. circuit at the- 9 time through the Q'Lwire oi the group (Fig. 1d), through b contacts of X2, b contacts of X5, 0 contacts of INT, to the 0 wire 35 (Fig. 1e), left hand contacts of DV2, the (1 segment 2? in the units order of the multiplicand accumulator, brush 26 and conductor 28, a contacts of relay R04 (now energized as will be explained), units socket 54 and plug connection 55 (Fig. lb) to units socket of the product accumulator (A00. 3), thence through n contacts of XIil (shifted), m contacts of T, in contacts of SHQ (shifted), h contacts f 31-12, h contacts of SHI, 1) contacts of A3 (shifted) and stop magnet 25 in column 6 position of accumulator 3. This impulse occurs at the 9 time and is concurrent with the start impulse sent at the same time to all of the start magnets in the product accumulators 2 and 3. This start impulse is traceable in Fig. lb from line 3i, 9 segment of emitter E3, wire 6| and thence through all the a contacts (shifted) of relaysA2 and A3, all the a contacts of relays M2 and M3 to all the start magnets 25 of accumulators 2 and 3.

It may be mentioned at this point that accumulators 2 and 3 are tied together electrically to constitute a single accumulator or" 12 column capacity by a plug connection 5'! (Figs. 1a and 1b) between carry contact sockets as shown. ihe control for the initial energization of relays A2 and A3 is brought about as follows. The impulse from contacts C; 7 (Fig. 1b) is plugged from sockets h], through connections 58 and 55 to the sockets 62 designated with a plus sign and related to accumulators 2 and 3, respectively, to energize the A2 and A3 relays through the q contacts to the balance relay BAL. A further parallel circuit also extends through connection 68 to the socketleading to the readout magnet R04 (Fig. 1e) of accumulator 4. The circuit through the magnets A2 and A3 extends through wire 43 (Figs. lb and la) to r contacts of X2 and X5, contacts CI5 to ground (see Fig. 12a).

t will be particularly noted in Fig, la that, when neither the X2 nor X5 relays are energized, the circuit from wire 33 (and the A and M relays) extends through contacts CI5, and the duration of energization is determined by the timing of these contacts. If relay X2 were in energized condition, the circuit would extend through and be controlled by contacts CI3 so that, as shown for the third cycle (Fig. 12a) the A and M relays would be deenergized for ashort period from 169 to 195. If relay X5 were in energized condition, the circuitwould extend through and be controlled by contacts CI l so that, as shown for the fourth cycle (Fig. 122:) the A and M relays would be deenergized for a short period from 101 to 125.

In the column 6 position of accumulator 3, therefore, the start and stop impulsesare concurrent and, since in this type of accumulator concurrent impulses to the start and stop magnets 2a'i will not change the condition thereof, that is, if the accumulator wheel is at rest, it will remain at rest.

In the tens order of the multiplicand accumulator, which is set-at the-complement 1, a similar circuit will be traceable at the 8 time in the cycle to energize the stop magnet 25 in the position 1 of accumulator2. This will occur one point after the start impulse so that this order will be advanced one step (see Fig. 10). In like manner and through similar circuits the 2 position of accumulator 2 will be advanced two steps; In all other positions, the wheel will advance as a result of theinitial start impulse until at the 0 time in 11 the cycle a stop impulse is transmitted from emitter E3 through the wire 50 as already traced to energize all the stop magnets.

It will be noted that as a result of this entry tens carry will take place in appropriate positions and that there will be a tens carry from the highest order through the plug connection 51 to the lowest order to enter the fugitive 1 therein, and at the end of the cycle the product accumulator will represent the complement of 789 followed by 00000.

The denominational location of the entries into the product and multiplier accumulators is dependent upon which of the shift relays SHI, SHZ or SH4 is energized. If the SIM relay is energized as for the instant example, there is an accumulator entry shift of four places to the left. If in addition thereto the XI relay is energized, there is an additional shift of one column.

It may be pointed out at this time that, if the SH2 relay is energized, there would be a column shift of two places. If the SI-Il relay is energized, there will be a column shift of one place. The SH2 and SI-ll together will cause a column shift of three places, 81-14 and SHI bring about a column shift of live places, etc., with any of these column shifts bein increased by 1 if there is an accompanying energization of the X|0 relay. As indicated in the timing diagram (Fig. 12a), the shift control relays SCI and SC4 drop out at the end of the first cycle upon opening of contacts C9 (Fig. 11) after having controlled the energization of the shift relay SE4.

Later in the second cycle, when the contacts 08a (Fig. 1f) close, a circuit is completed through 12 contacts of SH i (now closed), b contacts of R36 to energize relay SC4 again. Thereafter, contacts C6 open to deenergize SE4. At the testing time when the contacts 03 (Fig. now close, relays CAL and SC4 are in energized condition, so that the circuit is traceable to the common conductor 28 in the third highest position wherein the brush 26 is now set at the 1 segment (see Fig. 3) so that the circuit continues through the 1 wire 35 (Fig. 1d), thence through d contacts of BAL (now shifted), a contacts of MP2 (closed), it contacts of BAL (shifted) and the X2 relay to ground, which relay will now hold through contacts Cl into the next cycle. 1

With relay S04 energized, when contacts C4 (Fig. 1 close, relay 8H4 will be energized through the circuit from line 3|, wire 32, b contacts of S04 (closed), b contacts of R3| and relay SE4 to ground. This relay will hold through contacts C6 as before and at the end of the cycle, when contacts C9 open, relay SC4 will become deenergized leaving the setting transferred to the shift relay.

Near the end of the second cycle with relay BAL energized, the accumulator conditioning circuits from contacts Cl! (Fig. 11)) will extend to the sockets 42 as before, but for accumulator I (Fig. la) the circuit will extend through shifted q contacts of relay BAL to energize relay A| instead of MI. For accumulators 2 and 3, the circuits will extend through shifted p contacts of BAL to energize the relays M2 and M3 instead of A2 and A3. Since relay X2 is now in energized condition, the relays Al, M2 and M3 will be energized for two distinct periods as shown in Fig. 12a and under control of contacts C|3 as explained hereinabove. Briefly, when contacts CIT close, the energizing circuit extends from wire 43 (Fig. 1a), through contacts 12 CI3, 1' contacts of X5 and q contacts of X2 (shifted) to ground. This circuit is broken upon opening of contacts C|3 and remains open for a short period until reclosure of contacts CI3, after which it is held until contacts Cl'l open.

Third cycle Entering multiplier 2.-In this cycle 9,979,999 is to be entered in ACC. and 1578 is to be entered in A00. 2, 3. At the 9 time an impulse from emitter E3 (Fig. lb) extends from line 3|, 9 segment of emitter E3, wire 6| (Fig. la), through all the a contacts of relay A| (now closed), all the a contacts of relay MI to all the start magnets 25 of ACC. I so that in all orders the wheels commence to rotate (see Fig. 10).

In the third highest order, a stop circuit is traceable (Fig. 16) from line 3|, wire 44 to the 3 segment of emitter E| to the 3 wire 45 (Fig. 1d), m contacts of relay X2 (shifted), m contacts of relay X5, a contacts of INT to the 8 wire 35, a contacts of DV2, 8 wire 46, 2 contacts of CAL, to the plug socket 47 connected through connection 48 (Fig. 1a) to the units socket 49 of accumulator thence down through the 11. contacts of XIO, n contacts of T, n contacts of S114 (shifted), i contacts of SE2, 2' contacts of SHI, 1) contacts of Al (shifted) to the stop magnet 25 in the third highest order. The timing is such that the wheel will be stopped after six steps of advance, i. e., it starts at the 9 time and stops at 3. In all the other orders the wheels will be stopped after eight steps of advance through the circuit from the emitter E3 (Fig. lb) to the 1 segment, 2' contacts of relay X2 (shifted), 1' contacts of relay X5, wire 50 (Fig. 1a), b contacts of relay A| (now back in normal position), to the stop magnets 25. The manner in which the 2) contacts of relay AI are restored to normal prior to the completion of the stop circuit is as follows: the circuit to the AI relay, as explained, extends through contacts C|3 (Fig. la) which, as noted, open just before the 1 time in the cycle, so that the AI relay becomes deenergized at this time and the stop impulse may then extend through its contacts to stop the advance of the accumulator.

Just before the 0 time, the reclosure of contacts C|3 will reenergize the Al relay which will be held from wire 43, through contacts CI3, r contacts of X5, q contacts of X2 (shifted) to ground (it being recalled that contacts CI5 open just before 0). This circuit breaks when contacts CIT (Fig. lb) open. At the 0 time in the cycle, emitter E3 sends an impulse through its 0 segment, h contacts of relay X5, h contacts of relay X2 (energized), wire 6| (Fig. 1a), the now closed a contacts of the AI relay to energize all the start magnets 25 in accumulator After one additional step of movement, the emitter E3 will send a circuit through the 11 segment, wire 50, 2: contacts of relay Al which are now back in normal position to the stop magnets 25. The deenergization of the Al relay results from the opening of contacts C|l just be.- fore the 11 point in the cycle.

Following this, at the carry time the impulse to the 12 segment of emitter E3 will transmit the usual carry start impulse to wire 5| and the following impulse at the 13 time will extend to the stop impulse wire 50, through it contacts of X2 (which are now in normal position). The controlling magnet X2 was deenergized upon opening of contacts C! at the time indicated in the diagram (Fig. 12a). At the end of this cycle, 

